Navigation data processing system, apparatus and computer readable medium

ABSTRACT

A navigation system and a computer program are capable of changing the role of an apparatus that implements navigation in accordance with its performance and circumstances, and achieving single navigation, in a coordinated fashion, with multiple apparatuses to which their roles are appropriately distributed. At least one apparatus is provided with: a plurality of function executing units that independently have different functions for navigation, each of the function executing units performing processing associated with the function in response to a given instruction and returning a result of the processing; and an instruction unit that provides an instruction to each of the plurality of function executing units, and receives a result of the processing returned in response to the instruction; the instruction unit of the apparatus provides an instruction to one or more of the plurality of function executing units according to a procedure suitable for a purpose to be accomplished as to navigation, and outputs navigation data based on a result of processing returned in response to the instruction.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a Continuation application of U.S. application Ser.No. 16/323,500, which is the National Phase of PCT InternationalApplication No. PCT/JP2017/029274, filed on Aug. 14, 2017, which claimspriority under 35 U.S.C. 119(a) to Patent Application No. 2016-161480,filed in Japan on Aug. 19, 2016, all of which are hereby expresslyincorporated by reference into the present application.

FIELD

The present invention relates to a navigation data processing systemthat presents a route to a destination and information on the route, anapparatus belonging to the navigation data processing system and to acomputer readable medium storing a computer program.

BACKGROUND

The ownership rate of a hand-held communication device, which is aso-called smartphone, is very high, and the user can always carry ahand-held communication device and acquire information collected fromanother hand-held communication device or a server computer of a datacenter with the hand-held communication device at any place. Themajority of the hand-held communication devices these days have afunction of specifying the location of their own devices. The user canthus receive a navigation service for displaying the location of his orher own on a map as well as can use functions of calling, sending andreceiving of messages and etc. with the hand-held communication device.The user can receive a navigation service during traveling by carryingthe hand-held communication device into a vehicle even if the vehicle isnot mounted with a navigation device.

Meanwhile, as the technology of an on-vehicle navigation deviceprogresses, integration of various functions advances, such as fusion ofa retrieval function of information on availability of surroundingfacilities and a play-back function of music in addition to a routesearch function on a map and a guidance function along a route.

Irrespective whether they are for the hand-held communication device orthe on-vehicle navigation device, these navigation services are eachimplemented based on a computer program, while the size of the computerprogram tends to increase by the addition of various functions. Here,even in the case of adding or modifying one of the functions, all thefunctions are required to be updated since they are interdependent. Incontrast thereto, Japanese Patent Application Laid-Open Publication No.2002-318702 relates to a computer program in an on-vehicle navigationdevice, and proposes a program configuration in which a moduleassociated with an additional function is provided separately from amodule associated with a basic function, and the modules mutually haveinterfaces built-in for exchange of data to thereby facilitate additionof a function and enable reduction of the man-hours required fordevelopment.

SUMMARY

The hand-held communication device and the on-vehicle navigation devicehave advanced their developments while being directed to differentservices. As described above, however, both of the devices are carriedor mounted on a mobile unit, and can specify their own locations anddraw maps and the locations of their own on the maps by using mapinformation. In addition, both of the devices have the communicationfunctions to allow for cooperation with an external service andapplication to various services. That is, the hand-held communicationdevice and the navigation device have differences in a hardwareconfiguration and performance while having increasing overlappedfunctions.

In most cases, the user uses the navigation service implemented by thehand-held communication device in one situation and the on-vehiclenavigation device in another situation at his or her own discretion.However, it is highly expected that the cooperation between thehand-held communication device and the on-vehicle navigation devicewould improve the convenience of the user.

For the cooperation between the hand-held communication device and theon-vehicle navigation device, conceivable is a method of arranging afunction module for the basic function on the on-vehicle navigationdevice and arranging an extended module on the hand-held communicationdevice, and interfaces are incorporated in the respective devices topermit interaction with each other (refer to Japanese Patent ApplicationLaid-Open Publication No. 2002-318702). This makes it possible toseparately develop these devices, resulting in reduction in man-hours.In this case, however, the functions are fixedly given to the respectivedevices, such as the on-vehicle navigation device associated with thebasic function and the hand-held communication device associated withthe extended function, for example. This makes it difficult to respondto changes in circumstances such as the performance of the respectivedevices, changes of the communication environment and so on.

The present disclosure is made in view of these problems, and aims atprovision of a navigation data processing system capable of changing therole of an apparatus that implements navigation in accordance with itsperformance and circumstances, and achieving single navigation, in acoordinated fashion, with multiple apparatuses to which their roles areappropriately distributed, an apparatus belonging to the navigation dataprocessing system and a computer readable medium storing a computerprogram.

A navigation data processing system according to a first aspect of thepresent disclosure, includes: at least one apparatus including aprocessor, the processor configured to: execute function processes fordifferent functions concerning navigation, each of the functionprocesses including performing processing corresponding to the functionin response to a given instruction and returning a result of theprocessing; execute a single instruction process including providing aninstruction to each of the function processes and receiving a result ofprocessing returned in response to the instruction; provide instructionsto one or more of the function processes according to a proceduresuitable for a purpose to be accomplished as to navigation in executingthe instruction process; and output navigation data based on results ofprocessing returned in response to the instructions.

In a navigation data processing system according to a second aspect ofthe present disclosure, the processor executing the instruction processpreviously selects one or more of the function processes to be used outof the function processes for the purpose to be accomplished.

In a navigation data processing system according to a third aspect ofthe present disclosure, two or more of the apparatuses are included,each processor of at least any two of the apparatuses executes at leastone of the function processes corresponding to an equal function, andthe processor of one of the two apparatuses makes the function processof the equal function for use whereas the processor of the other one ofthe two apparatuses makes the function process unselected and unused inthe instruction process.

In a navigation data processing system according to a forth aspect ofthe present disclosure, the processor of each of the apparatuses, in theinstruction process, provides an instruction to a selected one of thefunction processes of its own apparatus or provides an instruction to aselected one of the function processes of another apparatus via acommunication medium.

In a navigation data processing system according to a fifth aspect ofthe present disclosure, the processor of the apparatus executesselection from the plurality of function processes at any timing duringoperation.

In a navigation data processing system according to a sixth aspect ofthe present disclosure, the processor executing the function processesand the instruction process input and output the instruction and theresult of processing by a command or a message.

A non-transitory computer readable medium storing a computer programaccording to one embodiment of the present disclosure, causes thecomputer to: execute function processes divided for different functionsconcerning navigation, each of the function processes including steps ofperforming processing corresponding to the function in response to agiven instruction and returning a result of the processing; and executea single instruction process including steps of providing an instructionto each of the function processes and receiving a result of a processingreturned in response to the instruction, the instruction processincluding the steps: providing instructions to one or more of thefunction processes according to a procedure suitable for a purpose to beaccomplished as to navigation; and outputting navigation data based onresults of processing returned in response to the instructions.

In one embodiment of the present disclosure, configuration is made by atleast one apparatus including a processor executing function processeseach performing a different function based on an instruction provided bya single instruction process. Each of the function processes outputs aresult of the processing in response to an instruction provided onlyfrom the instruction process capable of providing an instruction to eachof the function processes. The processor executing the instructionprocess receives the result and outputs information on navigation basedon the result. That is, the function processes each perform processingaccording to the instruction only from the instruction process and donot have mutual dependence among them, such as requesting anotherfunction process to perform processing. The processor executing theinstruction process causes the function processes for differentfunctions to perform processing by coordinating them with one another tothereby accomplish one purpose.

In one embodiment of the present disclosure, the function process to beused is selected depending on each purpose, and the role is dynamicallychanged among the apparatuses.

In one embodiment of the present disclosure, in the case of aconfiguration by the plurality of apparatuses, any two of theapparatuses may have function executing units corresponding to the samefunction. In this case, the function process of one of the apparatusesis used whereas the function process of the other one of the apparatusesperforming the same function is not used.

In one embodiment of the present disclosure, in the case where theoverlapped function processes are operable among the plurality ofapparatuses, if one of the function processes is selected, the functionprocess can also be used via the apparatus other than the apparatus inthe selected function process. At this time, an instruction is providedvia a communication medium, and the result is returned via thecommunication medium.

In one embodiment of the present disclosure, in each apparatus, afunction process to be selected is not fixed. That is, every time apurpose to be accomplished occurs, a different function process isselected at any timing for use.

In one embodiment of the present disclosure, exchange of data betweenthe function process and the instruction process is implemented bycommands, messages or the like. Since the exchange of data is notperformed by calling functions (API, etc.), independence between thefunction processes and the instruction process is enhanced, whichequalizes the exchange of data between the function processes and theinstruction process that are in different apparatuses with the exchangeof data between the function processes and the instruction process thatare in the same apparatus.

According to the embodiment of the present disclosure, the functionprocesses do not have mutual dependence developed among them, whichallows for interchange of the function modules corresponding to thefunction processes, a version upgrade and so on without affecting theentire system, and reduction of the man-hours required for developmentof the system. Each of the apparatuses can perform processingselectively using a necessary function process. The function processesand the instruction process are similarly made operable betweendifferent types of apparatuses, so that the use of the functionprocesses in different combinations for each of the differentapparatuses enables changes of the role of the apparatus and eliminatesthe need for previously fixing functions for each apparatus. That is,the role of the apparatus is not fixed to one and can be changed in realtime in accordance with its performance and circumstances. Theapparatuses each play a role in correspondence with its performance andcircumstances and accomplish in a coordinated fashion one purposeconcerning navigation, such as a route search, information retrieval andso on.

The above and further objects and features will more fully be apparentfrom the following detailed description with accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an explanatory view illustrating an outline of a navigationsystem according to the present embodiment.

FIG. 2 is a block diagram illustrating the hardware configurations ofapparatuses included in a navigation system according to a presentembodiment.

FIG. 3 is a flowchart illustrating one example of basic processing whena control unit functions as an instruction module.

FIG. 4 is an explanatory view illustrating a basic configuration of anavigation system according to a present embodiment.

FIG. 5 is an explanatory view illustrating another configuration of anavigation system.

FIG. 6 is an explanatory view illustrating another configuration of anavigation system.

FIG. 7 is an explanatory view illustrating operation of a navigationsystem in another situation.

FIG. 8 is an explanatory view illustrating operation of a navigationsystem in another situation.

MODES FOR CARRYING OUT THE INVENTION

The present invention will be described in detail below with referenceto the drawings illustrating the embodiments thereof. The embodimentsdisclosed below are to be construed as illustrative and not restrictivein all aspects.

It is to be noted that, as used herein and in the appended claims, thesingular forms “a”, “an”, and “the” include plural referents unless thecontext clearly dictates otherwise.

FIG. 1 illustrates the outline of a navigation system 100 according tothe present embodiment. The navigation system 100 includes at least anapparatus 1A and further includes apparatuses 1B and 1C that cancommunicate with the apparatus 1A as illustrated. In the exampleillustrated in FIG. 1, the apparatus 1A is a hand-held communicationdevice, which is a so-called smartphone, the apparatus 1B is a servercomputer constituting a data center, and the apparatus 1C is anavigation device mounted on a vehicle V. The navigation system 100 isachieved by causing the apparatuses 1A, 1B and 1C to execute processingbased on a common navigation program 1P.

The navigation program 1P is formed by a program module includingfunction modules 21-29 independently operating to perform respectivefunctions and an instruction module 20 instructing the function modules21-29 to operate. Note that the term “module” is used for both of themeanings of a program component included in a navigation program 1P aswell as an object activated by the computer (processor) executing eachof the program components. The function modules 21-29 include a mapinformation module 21, a location module 22, a search module 23, aretrieval module 24, a map drawing module 25, a vehicle information andcommunication system (VICS: registered trademark) module 26, a guidancemodule 27, a safety driving assistance module 28 and a cooperationmodule 29. The function modules 21-29 are configured to exchange datawith only the instruction module 20. One of the function modules 21-29does not directly depend on the other function modules 21-29. Theexchange of data between the function modules 21-29 and the instructionmodule 20 is performed not by a method of mutually calling functionscorresponding to the respective one of the modules but by a method ofproviding an instruction by a command, a message, or the like andreceiving a reply in response thereto.

The program configuration of the navigation program 1P including thefunction modules 21-29 with high independence first allows forinterchange of the function modules 21-29, a version upgrade withoutaffecting the entire system, and reduction of the man-hours required fordevelopment of the system. Secondly, the apparatus 1A executing thenavigation program 1P can execute processing by selectively using anecessary function out of the functions of the function modules 21-29during operation by the instruction module 20. The apparatus 1A is notrequired to have fixed functions within the system and can selectivelyuse the function modules 21-29 so as to suit its own performance andcircumstances. Moreover, the navigation program 1P is made to beexecuted in a similar manner in the different types of apparatuses 1A,1B and 1C, which eliminates the need for individually creating programsfor different apparatuses. For example, a distinction between a serverprogram and a client program is not required.

Accordingly, since the multiple apparatuses 1A, 1B and 1C can executeprocessing based on the same navigation program 1P, they do not havefixed functions and can selectively use functions so as to suit theirperformance and circumstances. In the situation where the instructionmodules 20 of the respective apparatuses 1A, 1B and 1C can send andreceive commands and messages or the like by communication, theapparatuses 1A, 1B and 1C can perform processing by selectively usingthe function modules 21-29 so as to suit their performance andcircumstances and can mutually complement their functions. Here, if acommunication connection is established among the apparatuses 1A, 1B and1C, the physical place where the processing is to be executed based oneach of the function modules 21-29 in response to the instruction is notlimited irrespective of where an instruction comes from among theinstruction modules 20 of the apparatuses 1A, 1B and 1C. Specifically,if the instruction module 20 of the apparatus 1A provides an instructionto the search module 23 for searching a route, the search module 23 ofthe apparatus 1B, not the apparatus 1A, may execute search, althoughdetailed description of the functions of the respective function modules21-29 will be made later.

In the navigation system 100 according to the present embodiment, theapparatus 1A can independently operate as the smallest unit as well ascan dynamically disperse the functions to be executed to the apparatus1B and the apparatus 1C to thereby achieve cooperative operation. Thefollowing describes the configuration and operation of the navigationsystem 100 in detail.

FIG. 2 is a block diagram illustrating the hardware configurations ofthe apparatuses 1A, 1B and 1C included in the navigation system 100according to the present embodiment. The apparatuses 1A, 1B and 1Cincluded in the navigation system 100 according to the presentembodiment each include at least a control unit 10, a temporary storageunit 11, a storage unit 12 and a communication unit 13 as illustrated inFIG. 2. The type and the detailed structure of the components may bedifferent among the apparatuses 1A, 1B and 1C. In FIG. 2, commoncomponents out of the components are denoted by reference codes A, B andC for identifying their belonging.

The control unit 10 implements the operation based on the navigationprogram 1P stored in the storage unit 12. The types of the CPU may bedifferent among the apparatuses. For example, multi-core CPUs with highconcurrent processing power are used for the CPU of the control unit 10Aof the apparatus 1A serving as a hand-held communication device and theCPU of the control unit 10B of the apparatus 1B serving as a servercomputer whereas a compact CPU incorporated in a microcomputer is usedfor the control unit 10C of the apparatus 1C serving as an on-vehicledevice. It is necessary for either CPU to be hardware resources capableof executing processing based on the navigation program 1P.

The temporary storage unit 11 uses a volatile memory and temporarilystores information generated by the processing of the control unit 10.Note that the temporary storage unit 11 may be configured to beincorporated in the control unit 10.

The storage unit 12 is a storage using a nonvolatile memory and storesvarious data to which the control unit 10 refers and data on the resultof the processing executed by the control unit 10 in addition to thenavigation program 1P. The storage unit 12, for example, storesinformation indicative of the performance of the apparatuses 1A, 1B and1C as well as version information of the function modules 21-29. Thetype of the storage unit 12 may also be different among the apparatuses1A to 1C. For example, the storage units 12A and 12C of the respectiveapparatuses 1A and 1C use flash memories whereas the storage unit 12B ofthe apparatus 1B uses a hard disk. The navigation program 1P stored inthe storage unit 12 may be recorded in a computer readable recordingmedium 3. The storage unit 12 stores a navigation program 3P read outfrom the recording medium 3 by a read-out device (not illustrated). Therecording medium 3 may be an optical disk such as a compact disk(CD)-ROM, a digital versatile disc (DVD)-ROM, a Blu-ray (BD; registeredtrademark) disk or the like, a magnetic disk such as a flexible disk, ahard disk or the like, a magneto-optical disk, a semiconductor memory,and so on. The navigation program 3P may be downloaded from an externalcomputer (not illustrated) connected to communication networks (notillustrated) and stored in the storage unit 12.

Any types of the communication unit 13 that allow for communicationbetween the apparatuses may be used. For example, the communication unit13A of the apparatus 1A serving as a hand-held communication deviceincludes multiple communication modules corresponding to wirelesscommunication with a base station, etc. provided by a communicationcommon carrier, and a short range wireless communication, such as Wi-Fi,Bluetooth (registered trademark), etc. The communication unit 13B of theapparatus 1B serving as a server computer corresponds to an opticalnetwork. The communication unit 13C of the apparatus 1C serving as anon-vehicle device includes multiple communication modules correspondingto wireless communication with a base station, a short range wirelesscommunication such as Wi-Fi, Bluetooth (registered trademark), etc. anda receiving unit for VICS, etc. Note that the communication unit 13 maybe able to send and receive at least common protocol data based onTCP/IP or UDP/IP.

At least one of the apparatuses 1A, 1B and 1C may have an inputinterface to be operated by the user while at least one of them maysimilarly have an output interface for displaying a map image and aroute concerning navigation and for outputting voice guidance. In theexample in FIG. 2, the apparatus 1A serving as a hand-held communicationdevice and the apparatus 1C serving as an on-vehicle navigation deviceeach have an operation unit 14 (14A, 14C) as an input interface as wellas a display unit 15 (15A, 15C) and a voice output unit 16 (16A, 16C) asoutput interfaces. The operation unit 14 accepts an operation input bydetecting a tap or the like on an operation screen including an icon,etc. displayed on the display via a touch panel integrated in thedisplay functioning as a display unit 15. The display unit 15 displaysan operation screen concerning navigation, a drawn map, a route, aguidance screen and so on by using the above-mentioned touch panelbuilt-in display. The voice output unit 16 outputs voice guidanceconcerning navigation by using a speaker.

FIG. 3 is a flowchart illustrating one example of basic processing whenthe control unit 10 functions as an instruction module 20. The controlunit 10 selects one or more of the function modules 21-29 to be used inits own apparatus or another apparatus (step S1). The function modules21-29 to be used are activated and wait for an instruction from theinstruction module 20. Note that the control unit 10 successivelyselects function modules as appropriate in accordance with the changesduring the operation based on the performance and usage of its ownapparatus at step S1. The criteria for selection here may vary dependingon the circumstances changing from moment to moment during operation ofthe apparatus 1 (various conditions including a position, an angle,another program that is being activated, the presence or absence ofanother apparatus) and the purpose such as what is to be done in thecircumstances as the navigation program 1P (search, retrieval, guidance,or the like) as will be described in detailed examples below. It isnoted that the purpose may preferably be a purpose to be accomplished bythe cooperative multiple apparatuses 1A, 1B and 1C as a whole (functionsin general regarding navigation such as attainment of a destination,provision of information on the actual location, etc.). Hence, thecontrol unit 10 may mutually select function modules with reference tothe presence or absence (activation) of another apparatus and theperformance of another apparatus by communicating with the control unit10 functioning as the instruction module 20 of another apparatus. If anyof the function modules 21-29 is selected based on the performance, someof the functions may not be used due to the restriction on the hardware.The control unit 10 may previously remove these unusable functions fromthe selection items. The criteria for selection are not limited thereto.

The control unit 10 provides an instruction to the function modules21-29 that are being selected and activated in accordance with thenecessity at that time point (step S2). The object to which aninstruction is provided may be the function modules 21-29 of anyapparatuses including its own apparatus and another apparatus. Thenecessity at that time point means the necessity for processing requireddepending on the purpose to be accomplished by the cooperative multipleapparatuses 1A, 1B and 1C as a whole (or by the apparatus 1A, 1B or 1Cindependently) as described above.

The control unit 10 outputs information concerning navigation to othersbased on a result returned from the function modules 21-29 in responseto the instruction (step S3). The “others” mentioned here may be thenext procedure based on the navigation program 1P or may be the outputinterface of its own apparatus or another apparatus, for example. It mayalso be another application program in cooperative with the navigationprogram 1P or may be another apparatus outside the system.

The following description will be made on, taking detailed examples, thefunction modules 21-29 selectively functioning among the apparatuses 1A,1B and 1C in accordance with the performance and circumstances in thenavigation system 100 thus configured.

FIG. 4 illustrates a basic configuration of the navigation system 100according to the present embodiment. The navigation system 100 can beoperated by a single apparatus 1A as the smallest unit. The scene wherethe navigation system 100 illustrated in FIG. 4 is used is a situationwhere the user examines a destination and the route before getting intothe vehicle V. The apparatus 1B is not included in the navigation system100 until a communication connection is performed from the apparatus 1A,and the apparatus 1C serving as the navigation device of the vehicle Vis not operated.

In the situation illustrated in FIG. 4, the control unit 10A of theapparatus 1A operates as the instruction module 20A based on theinstruction module 20 included in the navigation program 1P. The controlunit 10A of the apparatus 1A further operates as a map informationmodule 21A, a location module 22A, a search module 23A, a retrievalmodule 24A, a map drawing module 25A, a VICS module 26A, a guidancemodule 27A, a safety driving assistance module 28A and a cooperationmodule 29A based on the respective function modules 21-29.

The map information module 21A stores and reads out map information.Since the storage capacity of the apparatus 1A is smaller than that ofthe apparatus 1B, for example, the map information module 21A stores amap around the destination retrieved most recently or a map frequentlyused.

The location module 22A acquires the present location (location ofitself). The location module 22A of the apparatus 1A serving as ahand-held communication device acquires latitude-longitude informationusing a GPS receiver integrated in the apparatus 1A and further acquiresa more detailed location through communication with a base station byutilizing the Wi-Fi via the communication unit 13A.

The search module 23A searches the route to a destination. It accepts adeparture point and a destination, and outputs candidates for multipleroutes with reference to the map information and the trafficinformation.

The retrieval module 24A executes information retrieval. It accepts aretrieval keyword such as an address, a name, a genre and so on tothereby output the result of destination retrieval processing, as wellas accepts the information on a departure point, a present point or aroute to thereby output information on the facilities located aroundthem. The retrieval module 24A of the apparatus 1A basically requests anexternal search engine to perform retrieval processing via thecommunication unit 13A.

The map drawing module 25A accepts map information, a route and apresent position to thereby perform drawing (display) processing of themap, and the present position and the route on the map, etc., and outputimage data obtained by the drawing.

The VICS module 26A periodically acquires VICS information from anoptical beacon, a radio beacon or an FM radio wave, for example. In thecase where the apparatus 1A is provided with a receiving antenna for anFM radio wave, the VICS module 26A can acquire VICS information from anFM radio wave. In the case where the apparatus 1A is not provided with areceiving antenna, the VICS module 26A is made unused.

The guidance module 27A instructs the user for the traveling direction,guides handling operation such as left turn, right turn, etc. andattracts attention to a railroad crossing or the like based on thepresent location and the route by using voice and images.

The safety driving assistance module 28A performs driving assistancesuch as alerting the driver based on an input signal from a sensor, acamera and so on, or notifying the control system of the vehicle, or thelike of information. In the apparatus 1A serving as a hand-heldcommunication device, the safety driving assistance module 28A is madeunused as depicted by dotted lines.

The cooperation module 29A performs service other than the navigationsystem 100, for example, cooperation with a search engine. Thecooperation module 29A connects with an external service server usingthe communication unit 13A and outputs information based on a retrievalkeyword, for example.

The instruction module 20A provides a command to each of the functionmodules 21A-29A and receives the result of the processing in response tothe command. For example, the instruction module 20A first causes thedisplay unit 15A to display an operation screen and accepts operationperformed on the operation screen by the operation unit 14A. Theinstruction module 20A provides any of the function modules 21A-29A withan instruction command corresponding to the operation in accordance withthe accepted operation. The instruction module 20A then causes thedisplay unit 15A to display an image based on the result of theprocessing output from the function modules 21A-29A and causes the voiceoutput unit 16A to output voice.

The detailed situation illustrated in FIG. 4 is a situation where theuser intends to set a destination by using the apparatus 1A at homebefore departing from home by the vehicle V. At this time, in theapparatus 1A, the instruction module 20A provides the information on thename of the destination, etc. accepted by the operation unit 14A to theretrieval module 24A and causes the display unit 15A to output theresult of the retrieval processing output from the retrieval module 24A.The instruction module 20A provides the map information module 21A withthe location information (latitude-longitude information) of thedestination selected from the results of the retrieval processing andthe location information of the present location (the location where theapparatus 1A exists) acquired from the location module 22A to therebyacquire information on a neighboring map. The instruction module 20Aprovides the search module 23A with the location information of thedestination and the present position and the information on theneighboring map. The search module 23A outputs a search result, and theinstruction module 20A causes the display unit 15A to display the outputsearch result. If multiple candidates for the search result are output,selection is accepted by the operation unit 14A. In the example in FIG.4, the function modules 21A, 22A, 23A, 24A and 25A used in practice aredepicted by hatching.

Here, the instruction module 20A may temporarily hold the information onthe selected route in the storage unit 12A. The instruction module 20Amay then cause the display unit 15A to display the operation screenincluding icons for accepting an instruction for the start of guidance(leading) and the retrieval of information around the route, and maywait for operation.

The advantage of the navigation system 100 according to the presentembodiment is effectively produced when the navigation system 100 isformed by multiple apparatuses, although the navigation function can beperformed as described above by the apparatus 1A alone. FIG. 5illustrates another configuration of the navigation system 100. In theconfiguration illustrated in FIG. 5, the apparatus 1A is enabled tocommunicate with the apparatus 1B via the communication unit 13A, sothat the apparatus 1B participates in the navigation system 100. Theapparatus 1C serving as a navigation device of the vehicle V is notactivated.

In the situation illustrated in FIG. 5, the control unit 10B of theapparatus 1B operates as an instruction module 20B and each of thefunction modules 21B-29B. The functions of the instruction module 20Band the function modules 21B-29B are basically similar to those of therespective modules in the apparatus 1A. In the case of the apparatus 1B,however, the storage capacity of the storage unit 12B is far much largerthan those of the others, and the processing capability of the controlunit 10B is also higher than those of the others. The apparatus 1B isnot a mobile unit, and does not include an input interface and an outputinterface. The location module 22B, the VICS module 26B, the guidancemodule 27B and the safety driving assistance module 28B are alsoincluded in the navigation program 1P of the apparatus 1B. However,these modules are all unused as depicted by dotted lines since theapparatus 1B is not a mobile unit and does not include a hardware forreceiving VICS information or the like.

As illustrated in FIG. 5, in the case where the instruction module 20Band the instruction module 20A are enabled to exchange commands andmessages or the like by establishment of a communication connectionbetween them, the instruction module 20A of the apparatus 1A and theinstruction module 20B mutually exchange information concerning theirown performance. The instruction modules 20A and 20B determine that themap information module 21B is to be used in priority to the mapinformation module 21A since the map information module 21B has moredetailed map information than the map information module 21A as to themap information function, for example. The instruction modules 20A and20B exchange the result of the determination with each other and have acommon awareness of use of the map information module 21B of theapparatus 1B as to the map information. Likewise, the instructionmodules 20A and 20B have a common awareness of use of the search module23B and the retrieval module 24B of the apparatus 1B since the apparatus1B has high processing capability and high volume of obtainableinformation as to the search function and the retrieval function.

The detailed situation in the example illustrated in FIG. 5 is asituation where the user intends to set a destination at home by usingthe apparatus 1A before departing by the vehicle V, as in FIG. 4. In thesituation illustrated in FIG. 5, the apparatus 1A is enabled tocommunicate with the apparatus 1B, so that the function modules 21, 22,23, 24 and 25 that are actually to be used are dispersed to theapparatuses 1A and 1B as depicted by hatching.

Which apparatus including function modules 21-29 is to be used may bedetermined in accordance with the circumstances as well as theperformance. The instruction module 20A may, for example, select anappropriate map information module 21 based on the information on thedestination and route that are temporarily held in the storage unit 12Ain the situation depicted in FIG. 4. For example, the instruction module20A compares the region corresponding the map information to which themap information module 21A of the apparatus 1A can refer and the regioncorresponding to the map information to which the map information module21B of the apparatus 1B can refer, and uses the map information module21 suitable for a selected route (destination). If the destination iswithin a region used very frequently or a region used most recently, themap information module 21A is used. If, on the other hand, thedestination is within a region where the user visits for the first time,the map information module 21B of the apparatus 1B of the data centerwith high volume of information is used. In this case, when accepting bythe operation unit 14A selection of an icon corresponding to theretrieval on the operation screen displayed on the display unit 15A, theinstruction module 20A provides a command or message instructing forretrieval including a keyword upon retrieval to the retrieval module24B, not to the retrieval module 24A, via the instruction module 20B. Asdescribed above, the apparatuses 1A and 1B can respectively execute theretrieval modules 24A and 24B that perform the same function andsimilarly return the execution result. For the instruction module 20A,the result obtained by executing the retrieval may be returned to anyone of the apparatuses 1A and 1B. The instruction module 20A receivesthe retrieval result output from the retrieval module 24B by thecommunication unit 13A and displays it on the display unit 15.

Hence, in the navigation system 100, if the multiple apparatuses 1A and1B are enabled to communicate with each other, the functions to be usedare dispersed according to the usage or the performance of theapparatuses 1A and 1B, which achieves navigation in a cooperativemanner.

If the user starts the vehicle V based on the retrieved route, theapparatus 1C participates in the navigation system 100. FIG. 6 is anexplanatory view illustrating another configuration of the navigationsystem 100. In the scene where the navigation system 100 illustrated inFIG. 6 is used, the apparatus 1C serving as the navigation device of thevehicle V is activated and enabled to communicate with the apparatus 1Aand the apparatus 1B or any one of them by the communication unit 13C.

The control unit 10C of the apparatus 1C in the situation illustrated inFIG. 6 operates as an instruction module 20C and each of the functionmodules 21C-29C. The functions of the instruction module 20C and thefunction modules 21C-29C are basically similar to those of therespective modules in the apparatuses 1A and 1B. In the case of theapparatus 1C, the function modules 21C-29C including the safety drivingassistance module 28C are basically made usable since the apparatus 1Cis an on-board device mounted on the vehicle V.

When the engine or the motor starts to cause the vehicle C to travel asillustrated in FIG. 6 and to activate the apparatus 1C, the instructionmodule 20C starts to operate and is enabled to exchange commands,messages or the like with the instruction modules 20A and 20B of therespective apparatuses 1A and 1B. The instruction modules 20A, 20B and20C mutually exchange information on performance of their ownapparatuses.

The apparatuses 1A and 1C each have the operation unit 14, the displayunit 15 and the voice output unit 16. The instruction modules 20A and20C determine which operation unit 14, display unit 15 and voice outputunit 16 are to be used. Assume here that the user can select theinput-output interface of which one of the apparatuses 1A and 1C is tobe used on the operation screen displayed on the display unit 15A of theapparatus 1A. This allows the instruction modules 20A and 20C to have acommon awareness as to which one of the apparatuses 1A and 1C is to beused for its input-output interface. Note that the operation unit 14 ofthe apparatus 1A and the display unit 15C of the apparatus 1C may beselected for use or vice versa.

If it is determined that the apparatus 1A is not used as an input-outputinterface, the instruction modules 20A and 20C have a common awarenessof use of the operation unit 14C, the display unit 15C and the voiceoutput unit 16C as an input-output interface. The instruction modules20A and 20C have a common awareness of use of the location module 22Cand the guidance module 27C of the apparatus 1C as to the locationfunction and guidance function so as to suit the situation where theinput-output interface of the apparatus 1C is used, for example.Furthermore, the instruction modules 20A, 20B and 20C have a commonawareness of use of the VICS module 26C of the apparatus 1C providedwith an antenna for receiving a beacon radio wave as to the VICSfunction, and make the VICS module 26A that has been used up to thenunused. Hence, the instruction modules 20A, 20B and 20C dynamicallydetermine which apparatus including the function modules 21-29 is to beused in accordance with user's selection, the performance of therespective apparatuses, the circumstances and the function to beimplemented, and they cooperatively achieve presentation and guidance ofthe route during traveling.

As to another function, for example, the map information module 21 asdescribed above, a module of any of the apparatuses 1A, 1B and 1C fromwhich appropriate information can be acquired may be used. As to the mapdrawing module 25, the cooperation module 29 and so on, the instructionmodules 20A, 20B and 20C may make a determination among them as requiredsuch that the modules of any of the apparatuses 1A, 1B and 1C havingallowance for a processing load or a communication load are to be used.

In the situation as illustrated in FIG. 6, the instruction module 20Cstarts to operate, and the instruction modules 20A and 20C have a commonawareness of use of the location module 22C and the guidance module 27Cof the apparatus 1C as described above. Accordingly, the instructionmodule 20A sends the set (selected) information on the destination andthe route held by the storage unit 12A to the instruction module 20C.This eliminates the need for setting again the destination and the routethat were once set in the apparatus 1A in the navigation device of theapparatus 1C. Note that the instruction module 20A may automaticallysend the information on the destination and the route to the apparatus1C when detecting a communication connection with the apparatus 1C tothereby share the information.

In the case where the multiple apparatuses 1A, 1B and 1C are thusenabled to communicate with one another in the navigation system 100,the functions to be used are dispersed in accordance with theperformance (hardware) of the apparatuses 1A, 1B and 1C, the load or theuser's selection, so that the purpose of navigation is cooperativelyaccomplished.

Even in the case where the navigation system 100 is formed by theapparatuses 1A, 1B and 1C similarly to the configuration illustrated inFIG. 6, the function modules 21-29 to be used among the apparatuses 1A,1B and 1C vary in real time in accordance with the purpose of navigationother than the performance fixed to each of the apparatuses 1A, 1B and1C. FIG. 7 illustrates operation of the navigation system 100 in anothersituation. The detailed situation in the example illustrated in FIG. 7is a situation where the user being a driver or a passenger performsoperation of instructing retrieval of information on the neighborhood ofthe destination or search for another route by the operation unit 14C(or the microphone).

The instruction module 20C of the apparatus 1C, having receivedoperation, determines whether a search module 23C of itself or the otherinstruction modules 20A and 20B are to be used in view of thecommunication environment (good or bad connection state), the load ofthe control unit 10 and so on at that time. The instruction module 20Cselects an apparatus including the search module 23 to be used in viewof the result of the determination by the other instruction modules 20Aand 20B, and the instruction modules 20A-20C have a common awareness ofthe determination result. In the situation illustrated in FIG. 7, thesearch module 23B of the apparatus 1B is selected based on the fact thatthe present location is close to the destination, and the search module23B has the map information around the destination that is the easiestto be referred by the apparatus 1B and has a large volume of informationabout it, and has a low processing load. Here, the management module 20Cdetermines that establishing a direct communication connection with theapparatus 1B is unstable, and communicates with the apparatus 1B via theinstruction module 20A of the apparatus 1A. That is, a searchinstructing command is provided from the instruction module 20C to theinstruction module 20B via the instruction module 20A.

Hence, as illustrated in FIG. 7, the search module 23B and the mapinformation module 21B of the apparatus B that are being used aredisplayed by hatching and the search modules 23A and 23C are not used,as compared with the function modules 21-29 illustrated in FIG. 6. Inthe navigation system 100 according to the present embodiment, the rolesof the apparatuses 1A, 1B and 1C can dynamically be changed according tothe user's operation, that is, the purpose generated by the operation.

Note that when accepting an instruction for route search by theoperation unit 14C of the apparatus 1C, the management modules 20A, 20Band 20C may refer to the search histories stored in the apparatus 1A,the apparatus 1B or moreover a fourth apparatus not illustrated(personal computer at home). Note that by the cooperation module 29C or29A, the histories of the searched route are stored in association withthe identification information of the users in an external cloud serverso that the user can refer to the cloud server for the histories of theroute.

FIG. 8 illustrates the operation of the navigation system 100 in anothersituation. The situation illustrated in FIG. 8 is a situation where theuser parks the vehicle V at a parking lot and walks to the destinationby using the apparatus 1A. In the situation illustrated in FIG. 8, theapparatus 1C stops its operation and is not included in the navigationsystem 100 since the vehicle V is parked as illustrated. Thus, theinput-output interface to be used is changed from the apparatus 1C tothe apparatus 1A. By the instruction module 20C of the apparatus 1Cnotifying the instruction module 20A of the shift to the stopped state,the instruction module 20A can determine that the input-output interfaceof its own apparatus is to be used. At this time, the guidance module27A of the apparatus 1A is selected for use according to the purpose ofguiding the route as illustrated in FIG. 8. The map information module21B of the apparatus 1B with high volume of information because ofincluding a map around the destination and the map drawing module 25Bbased thereon are selected for use.

Hence, the navigation system 100 can dynamically change the roles of theapparatuses 1A, 1B and 1C in accordance with not only the operationperformed by the user but also various circumstances, such as thesituations of the apparatuses 1A, 1B and 1C constituting the system 100,the positional relation between the route being guided and the presentposition, changes of communication environment, traffic informationreceived by the VICS module 26C, and so on. In addition, even if thefunction modules 21-29 to be used are changed among the apparatuses 1A,1B and 1C in accordance with the change of the circumstances, the userdoes not recognize it. Furthermore, the user can seamlessly use theapparatus 1A and the apparatus 1C each of which have an input-outputinterface in order to achieve one purpose such as guidance to adestination, which significantly improves the convenience of the user.

Any apparatus other than the apparatuses 1A, 1B and 1C may participatein the navigation system 100 if only the apparatus can execute thenavigation program 1P according to the present embodiment. In theexample illustrated in FIGS. 4-8, only the apparatuses 1A and 1Cconcerning the same user or the vehicle V and the apparatus 1B servingas a server computer of the data center are configured to cooperate withone another. However, the navigation device of another vehicle drivingon the opposite lane to the vehicle V or another vehicle driving in thesame direction may also be included in the navigation system 100 so asto cooperate with the vehicle V. By using the route information held bythe instruction module 20 operating in the navigation device of anothervehicle (congestion predication based on a large number of vehiclestraveling in the same direction), traffic information (congestion stateof the destination) and so on, more efficient route search and the likemay be implemented. Moreover, the navigation device of another vehicleor another hand-held communication device existing in the vicinity ofthe destination may also be included for cooperation. This makes itpossible to predict the congestion state of a parking lot at thedestination or the surrounding parking lots based on the informationobtainable from the instruction module 20 of the apparatus existing inthe destination, for example. Hence, it is possible to enhance the levelof satisfaction with the navigation service by achieving moreappropriate route search and guidance, and retrieval with highsimultaneousness and high accuracy.

Various type of apparatuses including an immovable apparatus such as apersonal computer installed in a shop, for example, not limited to thenavigation device and the hand-held communication device, may executethe processing based on the navigation program 1P according to thepresent embodiment to form the navigation system 100. Exchanges of dataamong the instruction modules 20 of the various type of apparatusesenable improvement in the navigation service, such as automaticselection of a suitable route based on traffic information, setting offuel efficiency, and so on.

It should be understood that the embodiments disclosed above areillustrative and non-restrictive in every respect. Since the scope ofthe present invention is defined by the appended claims rather than bythe description preceding them, all changes that fall within metes andbounds of the claims, or equivalence of such metes and bounds thereofare therefore intended to be embraced by the claims.

What is claimed is:
 1. A navigation data processing system, comprisingat least one apparatus including a processor, the processor configuredto: execute function processes for different functions concerningnavigation, each of the function processes including performingprocessing corresponding to the function in response to a giveninstruction and returning a result of the processing; execute a singleinstruction process including providing an instruction to each of thefunction processes and receiving a result of processing returned inresponse to the instruction; provide instructions to one or more of thefunction processes according to a procedure suitable for a purpose to beaccomplished as to navigation in executing the instruction process; andoutput navigation data based on results of processing returned inresponse to the instructions.
 2. The navigation data processing systemaccording to claim 1, wherein the processor executing the instructionprocess previously selects one or more of the function processes to beused out of the function processes for the purpose to be accomplished.3. The navigation data processing system according to claim 2, whereintwo or more of the apparatuses are included wherein each processor of atleast any two of the apparatuses executes at least one of the functionprocesses corresponding to an equal function, and wherein the processorof one of the two apparatuses makes the function process of the equalfunction selected for use in the instruction process whereas theprocessor of the other one of the two apparatuses makes the functionprocess of the equal function unselected and unused in the instructionprocess.
 4. The navigation data processing system according to claim 3,wherein the processor of each of the apparatuses, in the instructionprocess, provides an instruction to a selected one of the functionprocess of its own apparatus or provides an instruction to a selectedone of the function process of another apparatus via a communicationmedium.
 5. The navigation data processing system according to claim 2,wherein the processor of the apparatus executes selection from thefunction processes at any timing during operation.
 6. The navigationdata processing system according to claim 1, wherein the processorexecuting the function processes and the instruction process input andoutput the instruction and the result of processing by a command or amessage.
 7. An apparatus belonging to a navigation data processingsystem, the apparatus comprising: a non-volatile memory configured tostore a navigation program; and a processor performing processing basedon the navigation program, wherein the processor configured to: executefunction processes for different functions concerning navigation, eachof the function processes including performing processing correspondingto the function in response to a given instruction and returning aresult of the processing; execute a single instruction process includingproviding an instruction to each of the function processes and receivinga result of processing returned in response to the instruction; provideinstructions to one or more of the function processes according to aprocedure suitable for a purpose to be accomplished as to navigation inexecuting the instruction process; and output navigation data based onresults of processing returned in response to the instructions.
 8. Anon-transitory computer readable medium storing a computer programcausing a computer to execute navigation data processing, wherein thecomputer program causes the computer to: execute function processesdivided for different functions concerning navigation, each of thefunction processes including steps of performing processingcorresponding to the function in response to a given instruction andreturning a result of the processing; and execute a single instructionprocess including steps of providing an instruction to each of thefunction processes and receiving a result of a processing returned inresponse to the instruction, wherein the instruction process includesthe steps: providing instructions to one or more of the functionprocesses according to a procedure suitable for a purpose to beaccomplished as to navigation; and outputting navigation data based onresults of processing returned in response to the instructions.